Automatic elastomer extrusion apparatus and method
The present invention relates to an automatic elastomer extrusion apparatus and method. An apparatus 400 for in-situ extrusion of an elastomeric coating 410 on a profiled helical surface 450 can include a template (100, 200) forming a gap between the profiled helical surface 450 and an adjacent profiled helical surface (102, 202) of a template (100, 200) itself to extrude an elastomer therethrough. A tracking mechanism 302 and/or carriage 300 can allow a template to follow the contours of the profiled helical surface 350. The apparatus can include means for providing relative movement between the profiled helical surface and the template. The apparatus (500, 600) can include a cleaning module (502, 602), an adhesive application module (504, 604), an elastomer deposition module (506, 606), and/or a curing module (508, 608). Each module can further include a template (100, 200) and/or a tracking mechanism 302.
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This application claims priority to U.S. patent application filed Jul. 31, 2006 as Ser. No. 11/496,563 (US Published App. No. 2008-0023123), incorporated herein by reference.
BACKGROUNDThe invention relates generally to extruding an elastomer. More particularly, the invention relates to an automatic elastomer extrusion apparatus and a method for extruding an elastomer onto a rotor or inside a stator of a progressive cavity motor or pump.
Progressive cavity pumps or motors, also referred to as a progressing cavity pumps or motors, typically include a power section consisting of a rotor with a profiled helical exterior surface disposed within a stator with a profiled helical interior surface. The rotor and stator of a progressive cavity apparatus operate according to the Moineau principle, originally disclosed in U.S. Pat. No. 1,892,217.
In use as a pump, relative rotation is provided between the stator and rotor by any means known in the art, and a portion of the profiled helical exterior surface of the rotor engages the profiled helical interior surface of the stator to form a set of sealed chambers or cavities. As the rotor turns eccentrically within the stator, the cavities progress axially to move any fluid present in the cavities.
In use as a motor, a fluid source is provided to the cavities formed between the rotor and stator. The pressure of the fluid causes the cavities to progress resulting in relative rotation between the stator and rotor. In this manner fluidic energy can be converted into mechanical energy.
As progressive cavity pumps or motors rely on a seal between the stator and rotor surfaces, one of or both of these surfaces preferably includes a resilient or dimensionally forgiving material. Typically, the resilient material has been a layer of elastomer disposed on the profiled helical interior surface of the stator, but can be disposed on the profiled helical exterior surface of the rotor. The stator and rotor are typically made of steel.
In use, the heat and stress encountered can cause cracking and other wear of the elastomer. A hydrocarbon or other caustic fluid can cause degradation of the elastomer. Regardless of the cause, it can be desirable to replace or otherwise automatically extrude a layer of elastomer on a profiled helical surface.
SUMMARYThe present invention relates to a method and apparatus for extruding an elastomeric coating on a profiled helical surface or redressing a pre-existing elastomeric coating. An apparatus can include a template having a surface spaced relative to the profiled helical surface to create a gap therebetween, a source of an elastomer in communication with the gap, and at least one tracking mechanism connected to the template and retained against the profiled helical surface. The tracking mechanism can be resiliently held against, or otherwise fixed into contact with, the profiled helical surface. The apparatus can include means for extruding the elastomer through the gap. The apparatus can include means for providing relative movement between the profiled helical surface and the template. The movement can be axial and/or rotational. The at least one tracking mechanism can be at least one wheel. A drive apparatus can be connected to the at least one wheel. The profiled helical surface can be an interior surface of a stator or an exterior surface of a rotor. The apparatus can further include means for removing a pre-existing elastomeric coating from the profiled helical surface, means for applying an adhesive on the profiled helical surface, and/or means for curing the elastomeric coating. The apparatus can include means for providing relative movement between the profiled helical surface and the apparatus or for providing relative movement between the profiled helical surface and each of the template and the respective means for removing, applying, and curing.
In another embodiment, an apparatus for extruding an elastomeric coating on a profiled helical surface can include a carriage disposed adjacent the profiled helical surface, a cleaning module, an adhesive application module, an elastomer deposition module including a template having a surface spaced relative to the profiled helical surface to create a gap therebetween and a source of an elastomer in communication with the gap, and a curing module each disposed on the carriage, and a traversal apparatus connected to the carriage for traversing the profiled helical surface.
The elastomer deposition module can include means for extruding the elastomer through the gap. The elastomer deposition module can include at least one displacement servo to maintain an orientation of the template relative to the profiled helical surface. The carriage can include at least one displacement servo to maintain an orientation of an assembly of the modules relative to the profiled helical surface. The adhesive application module can include a second template having a surface spaced relative to the profiled helical surface to create a second gap, and a source of an adhesive in communication with the second gap. The adhesive application module can include at least one displacement servo to maintain an orientation of the second template relative to the profiled helical surface.
The cleaning module can be disposed adjacent a first end of the carriage and the curing module adjacent a second end of the carriage, the adhesive application module can be disposed adjacent the cleaning module and the elastomer deposition module can be disposed between the adhesive application module and the curing module. The traversal apparatus can include at least one tracking mechanism resiliently held against the profiled helical surface. The carriage can be rotatable about a longitudinal axis of the profiled helical surface. The apparatus can include a rotational drive apparatus connected to the profiled helical surface to rotate the profiled helical surface during deposition of an elastomer.
The traversal apparatus can include a guide connected to the carriage and following at least one track extending in a straight line parallel to a longitudinal axis of the profiled helical surface as the profiled helical surface is rotated relative to the at least one track. The traversal apparatus can include a drive apparatus connected to the carriage to drive the carriage along the profiled helical surface and/or at least one wheel resiliently held against the profiled helical surface. A drive apparatus can be connected to the at least one wheel to drive the carriage along the profiled helical surface.
In another embodiment, a method of extruding an elastomeric coating on a profiled helical surface can include providing a template having a surface spaced relative to the profiled helical surface to create a gap therebetween, the gap in communication with a source of an elastomer, extruding the elastomer on the profiled helical surface through the gap, and providing relative movement between the profiled helical surface and the template, the template tracking the profiled helical surface with at least one wheel resiliently held against the profiled helical surface. The relative movement can be provided by powering a drive apparatus connected to the at least one wheel.
In yet another embodiment, a method of extruding an elastomeric coating on a profiled helical surface can include disposing a carriage with a cleaning module, an adhesive application module, an elastomer deposition module, and a curing module mounted thereto along the profiled helical surface, removing a pre-existing elastomeric coating with the cleaning module from a section of the profiled helical surface as the carriage is disposed along the profiled helical surface, applying an adhesive with the adhesive application module on the section of the profiled helical surface where the pre-existing elastomeric coating has been previously removed by the cleaning module, extruding an elastomer through a gap formed between a template of the elastomer deposition module and the profiled helical surface on the section of the profiled helical surface where the pre-existing elastomeric coating has been previously removed with the cleaning module and the adhesive has been previously applied with the adhesive application module, and curing the elastomeric coating with the curing module on the section of the profiled helical surface where the cleaning, adhesive application, and elastomer deposition modules have previously removed the pre-existing elastomeric coating, applied the adhesive, and deposited the elastomeric coating. The method can include positioning the template with at least one tracking mechanism connected to the template and resiliently held against the profiled helical surface. The template can be positioned with at least one displacement servo disposed between the template and the carriage.
The cleaning, applying, extruding, and curing steps can occur concurrently to a different portion of the rotor/stator. Relative movement can occur between the carriage and the profiled helical surface during the cleaning, applying, extruding, and curing steps. The method can include providing relative movement between the carriage and each of the cleaning module, the adhesive application module, the elastomer deposition module, and the curing module during the cleaning, applying, extruding, and curing steps.
The method can also include connecting a guide to the carriage, the guide following at least one track extending in a straight line parallel to an axis of the profiled helical surface, connecting at least one tracking mechanism to the carriage, the at least one tracking mechanism resiliently held against the profiled helical surface, and imparting relative rotation between the profiled helical surface and the carriage to drive the carriage along the track and the profiled helical surface.
The template in
To use, the template 100 is disposed adjacent to a profiled helical surface, for example, the exterior surface of a rotor. In a typical die for extruding an elastomeric tube, the extrusion gap is formed between a mandrel and a land (also referred to as a die aperture or bearing) in the cap of the die itself. An example of a profiled helical tube formed by extrusion is found in Published US Patent Application 2008-0023863, herein incorporated by reference. The present invention allows a gap to be formed between the exterior surface of a rotor (or interior surface of a stator with a template as shown in
Relative movement between the template and rotor surface can then be added to facilitate extrusion along the surface of the stator. The profiled helical shape of the aperture 102 of the template 100 permits a gap therebetween, and any elastomer extruded therethrough, to be of uniform thickness due to the parallel aperture and rotor surfaces. An optional adhesive can be applied to the helical profiled surface before extrusion to aid in the adhesion of the elastomeric coating by one or more spray nozzles, template, and/or brushes. An optional cleaning step can remove any pre-existing elastomeric coating and/or contaminants by chemical, thermal, hydraulic, cutting, scraping, and/or abrasive action. After extrusion, the elastomeric coating can then be cured by any means known in the art, which can include using pressure, heat, ultraviolet light, and/or the passage of time.
Similarly, if an elastomeric coating is to be formed on the profiled helical interior surface of a stator, a template 200 with an outer profiled helical surface 202 such as in
To allow the template (100, 200), to follow the helical pattern of the profiled surface, a tracking mechanism can be used. A tracking mechanism can be retained into contact with the profiled helical surface or can be resiliently held against the profiled helical surface, of a stator or rotor for example. The resilient force can be through a wheel constructed of a resilient material, for example, urethane, or by adding a shock absorbing member to the tracking mechanism. A plurality of tracking mechanisms can be used. A tracking mechanism allows the template, or carriage, to follow the contours of the profiled helical surface as relative movement is imparted between the template and profiled helical surface.
In a preferred embodiment, the longitudinal axis of the template and the longitudinal axis of the profiled helical surface remain concentric during the relative movement therebetween. A tracking mechanism can be a wheel, track, or skid, for example. A tracking mechanism can ride in the valley between each lobe of the profiled surface (see
A carriage 300 can also allow for the mounting of a cleaning module, an adhesive application module, an elastomer deposition module, and/or a curing module, as discussed in reference to
A tracking mechanism can include a drive apparatus, for example, the drive apparatus can be connected to a wheel to advance the tracking mechanism, and thus any template connected thereto, along the profiled helical surface.
Referring now to
In use, a profiled helical surface, for example, a rotor 450, is disposed within the profiled helical aperture 102 of the template 100 to allow in-situ extrusion of an elastomer. The profiled helical aperture 102 and the profiled helical exterior surface of the rotor 450 are design adjustable to create a gap therebetween. This gap can be of uniform or varying thickness around the circumference, as is known in the art. An elastomer can then be extruded through the gap by any means know in the art. A supply of elastomer can be carried by the extrusion means itself, for example, a double screw press, or supplied by umbilical to the extrusion means. The gap can be substantially the thickness of the formed elastomeric coating 410 if the elastomer retains its as extruded dimensions after curing, if required.
Relative movement can then be provided between the template 100 and the rotor 450 during extrusion to permit the template to track the rotor's 450 helical surface, and accordingly coat the rotor with a desired thickness of elastomeric coating 410. The rotor 450 can be coated with an adhesive prior to extrusion to aid in the adhesion of the elastomeric coating 410 to the profiled helical surface. Relative movement can be imparted by mechanical or electromagnetic force applied to one or both of the profiled helical surface 450 and template 100, for example, a template and/or a rotor can be moved by driving a wheel or set of wheels connected to the template and resiliently held against the rotor surface along the helical pattern of the rotor. By disposing at least one tracking mechanism substantially parallel to the path formed by a lobe or valley of the profiled helical surface, at least one tracking mechanism, for example a wheel, can be powered to create the relative movement between template and rotor, for example. A wheel can have an outer surface that allows for traction between the wheel and the rotor surface, which is typically smooth steel.
If primarily relative axial movement between the longitudinal axis of the rotor 450 and the longitudinal axis of the template 100, as defined by the helix of each, is imparted, rotation of the template 100 about the longitudinal axis of the rotor 450 can also be added to permit the template 100 to track the helical pitch of the rotor 450. The relative axial movement can be achieved by powered means, for example an electric motor rotating the template and/or rotor, or unpowered means, for example at least one tracking mechanism immovably, but can be adjustable, connected to the template to tracks the surface of the rotor, but allowing for movement between the profiled helical surface and the tracking mechanism, for example, the rotation of a wheel. Due to the helical pattern, the tracking mechanism can serve as a guide to allow the template to rotate about the axis of the rotor, or stator, as relative axial movement is imparted between the template and rotor, or stator.
Relative axial movement can be achieved by mechanical or electrical means, for example, by powering a drive wheel against a surface, said surface not limited to the profiled helical surface but can be, for example, a planar surface extending substantially parallel to the longitudinal axis of the rotor.
Referring again to
Although
The cleaning module 502 can remove a pre-existing elastomeric layer 501, if present, through any means known in the art. The cleaning module 502 can clean any contaminants from the exterior surface of the rotor 550, for example, rust or scale. The cleaning module 502 can utilize heat, chemical, cutting, scraping, and/or abrasive action.
The adhesive application module 504 can apply a thin controlled layer of adhesive through any means known in the art, if the use of adhesive is desired. For example, an adhesive application module 504 can include one or more spray nozzles and/or brushes. An adhesive application module 504 can include a template to apply a desired thickness of adhesive. A source of adhesive can be provided in communication with the template to dispense the adhesive through the gap between the template and the profiled helical surface. The source of adhesive can be carried by the adhesive application module 504 itself or provided by an umbilical as is known in the art. The umbilical can include a swivel device.
The design and/or orientation of the template relative to the profiled helical surface can control the geometry of the gap. In a preferred embodiment for use with an exterior profiled helical surface, such as the exterior surface of the rotor 550, a template is designed with an aperture whose inner surface is spaced relative to the circumference of the profiled helical surface to create a gap therebetween. The gap can be of variable thickness, for example, around the circumference or of uniform thickness, as is known in the art. A template can have any shape of profiled interior or exterior surface. A template can include a profiled helical aperture (for use with a rotor) or exterior (for use with a stator) surface or a profiled surface with a straight longitudinal aperture or exterior surface. Any of the cleaning module 502, the adhesive application module 504, the elastomer deposition module 506, and the curing module 508 can employ a template.
A template used with an exterior profiled helical surface can have an inner aperture geometry that is relatively smaller than the circumference of the rotor with an elastomeric coating (501, 509). A template thus can have radial slits or other elements to allow the template to expand such that a module with a template, for example the adhesive application module 504, can be removed from the rotor 550.
To allow any module (502, 504, 506, 508), which can include a template and/or a tracking mechanism, to traverse the profiled helical surface, a traversal apparatus can be employed. A traversal apparatus can allow axial and/or radial movement with respect to a module (502, 504, 506, 508) and/or template and the profiled helical surface. The profiled helical surface can be displaced, any module (502, 504, 506, 508) can be displaced, or any combination thereof.
A traversal apparatus can include a drive apparatus to impart relative movement between the automatic elastomer depositing apparatus 500 and the profiled helical surface and/or include a tracking mechanism to allow the automatic elastomer depositing apparatus 500 to track the profiled helical surface along the helix. A wheel, skid, or a continuous belt can be used as a tracking mechanism. The tracking mechanism can be resiliently held against the profiled helical surface and connected to a module (502, 504, 506, 508) and/or template. For example, if at least one wheel is used as a tracking mechanism, the wheel can be retained against any portion of the profiled helical surface to track the profiled helical surface. A profiled helical surface typically includes multiple lobes, with an apex of each lobe and a valley between each lobe. A wheel, or plurality of wheels, can, for example, be disposed in a valley and/or against an apex of a lobe. When relative movement is imparted between the wheel and the profiled helical surface, the wheel can track the profiled helical surface. By connecting the wheel and/or other tracking mechanism to a module (502, 504, 506, 508) and/or template, the module and/or template can track the contours of the profiled helical surface as the module and/or template is disposed down the axis of the profiled helical surface. An apex of a lobe of a profiled helical surface, for example the rotor 550, can thus remain adjacent a lobe of a template with a profiled aperture, if utilized, during movement of the profiled helical surface with respect to the template. As the tracking mechanism, and any module (502, 504, 506, 508) and/or template connected thereto, is disposed along the axis of the profiled helical surface, the tracking mechanism follows the contours of the profiled helical surface by rotating at the same pitch of the profiled helical surface. This can allow the gap to remain uniform with respect to the full length of the profiled helical surface as a module (502, 504, 506, 508) and/or template is disposed along the surface of the profiled helical surface.
As a module (502, 504, 506, 508) and/or template can be susceptible to positioning errors with respect to a desired alignment with the profiled helical surface, at least one displacement servo can be utilized. A plurality of displacement servos can allow independent radial movement with respect to each module (502, 504, 506, 508), tracking mechanism, template, and/or the profiled helical surface. A displacement servo can allow precise control of the gap formed between a template and the adjacent section of the profiled helical surface. The displacement servo, for example, can be connected between a template, if used, and a module (502, 504, 506, 508) or tracking mechanism.
The invention can also include an elastomer deposition module 506 which deposits an elastomeric coating 507 on the profiled helical surface. The means for depositing an elastomeric coating 507 can include means for extrusion, one or more spray nozzles and/or brushes, or any other means known in the art for depositing an elastomeric coating. In a preferred embodiment, an elastomer deposition module 506 includes at least one template, as disclosed above and means for extruding an elastomer through the gap. In an embodiment for use with a rotor 550, a template is designed with an inner surface of an aperture that creates a desired gap between the template and the profiled helical surface. Any template can have a profiled helical or non-helical surface without departing from the spirit of the invention. A source of an elastomer is in communication with the gap and the elastomer is extruded or otherwise disposed onto the profiled helical surface, shown in
The curing module 508 can apply heat, light, or otherwise cure the elastomeric coating through any means know in the art. A template can be utilized if desired to ensure uniform curing, for example, uniform heat application through a profiled heating coil.
In use, the automatic elastomer depositing apparatus 500 is disposed against the profiled helical exterior surface of a rotor 550, which can have a pre-existing elastomeric coating 501. Relative movement is then imparted between the automatic elastomer depositing apparatus 500 and the profiled helical surface of the rotor 550. The automatic elastomer depositing apparatus 500 can allow movement of each respective module (502, 504, 506, 508) in unison or individually. The relative movement can be imparted through any type of traversal apparatus or traversal means.
During the relative movement, the cleaning module 502 can remove any pre-existing elastomeric coating 501 and/or other contaminants to expose the rotor surface 503. Adhesive can then be applied to the cleaned rotor surface 503 with an adhesive application module 504, which can include a template tracking the profiled helical surface with at least one tracking mechanism. An elastomeric coating 507 is then applied to the adhesive coated surface 505 with the elastomer deposition module 506, which can include a template tracking the profiled helical surface with at least one tracking mechanism. The uncured elastomeric coating 507 can then be cured with the curing module 508, to create a rotor 550 with a cured elastomeric coating 509. Although the curing module 508 is illustrated in
The automatic elastomer depositing apparatus 500 can allow any of the modules to be activated at any time. For example, all of the modules (502, 504, 506, 508) can act on the profiled helical surface concurrently. This can allow the redressing of an elastomeric coating 509 with one pass of the automatic elastomer depositing apparatus 500 along the profiled helical surface of the rotor 550.
Any means known in the art can be utilized to provide relative movement between any of the respective modules (502, 504, 506, 508) and the profiled helical surface of the rotor 550. The means for providing relative movement can be a separate traversal module for use in addition to the other modules (502, 504, 506, 508) or each respective module (502, 504, 506, 508) can include its own respective traversal apparatus. To provide relative movement between the modules (502, 504, 506, 508) and the profiled helical surface of the rotor 550, a carriage can be employed. The carriage can allow the mounting of any of the modules (502, 504, 506, 508) in combination or alone. A plurality of carriages can be used without departing from the spirit of the invention. A carriage can be formed with a flexible connection between the modules (502, 504, 506, 508). A carriage can include at least one traversal apparatus, for example, a drive apparatus and/or tracking mechanism to allow the carriage to track the profiled helical surface. A drive apparatus and/or tracking mechanism can be mounted anywhere on the carriage and/or on the modules (502, 504, 506, 508). A drive apparatus and/or tracking mechanism can form a separate module which is attached to the carriage. A carriage embodiment is preferably utilized with a profiled helical surface with a constant pitch. If a carriage is used, a plurality of tracking mechanisms can be employed to support the entire automatic elastomer depositing apparatus 500 against the profiled helical surface.
In a preferred embodiment, at least one tracking mechanism is disposed between the cleaning module 502 and the adhesive application module 504 to allow the tracking mechanism to contact the cleaned rotor surface 503. In a preference embodiment, the configuration of tracking mechanisms shown in
The tracking mechanism, for example, a wheel, can include a drive apparatus connected thereto to drive the cleaning module along the profiled helical surface. The tracking mechanism can be attached to a template, if present. A traversal apparatus can include a separate drive mechanism to propel the traversal apparatus with respect to the profiled helical surface independent of the presence of a tracking mechanism. A traversal apparatus can include any means to provide relative axial and/or radial movement.
A carriage is not required and relative movement can be imparted to each module (502, 504, 506, 508) with respect to the profiled helical surface of the rotor 550, independent of the other modules. For example a module (502, 504, 506, 508) can include its own respective traversal apparatus, for example, a tracking mechanism and/or drive apparatus. Each respective tracking mechanism can have a drive apparatus which is connected to the tracking mechanism, for example, a wheel, to provide relative movement between the module (502, 504, 506, 508) and the profiled helical surface. Each module can have a differing rate of traversal. The physical gap between the modules, independent of the use of a carriage, and/or speed at which the automatic elastomer depositing apparatus 500 functions can be dependent upon the traction of the means for relative movement, the speed at which each module can be moved, the cleaning, adhesive application, elastomeric coating deposition, and curing process times, amount of radiated heat during the curing process, and/or vibration. Each module (502, 504, 506, 508) can be moved independently or in a coordinated movement with the other modules depending on the desired rate of traversal for each respective module. If a carriage is used, the carriage can be moved at a rate equal to the rate of the slowest traversing module (502, 504, 506, 508).
An optional rotational drive apparatus can allow rotation of the profiled helical surface, for example about a longitudinal axis. If an optional rotational drive apparatus is used, a traversal apparatus can include at least one track extending in a straight line parallel to the longitudinal axis of the profiled helical surface. A guide is provided to follow the track, with the guide being attached to a carriage or a module (502, 504, 506, 508). A carriage or a module (502, 504, 506, 508) can include a tracking mechanism, for example a wheel. As the profiled helical surface, for example the rotor 550, is rotated about the axis, a tracking mechanism follows the contours of the profiled helical surface. By connecting the tracking mechanism to a guide which follows a straight line track, the rotation of the profiled helical surface is translated into axial movement of the carriage or module (502, 504, 506, 508) to which the tracking mechanism and guide are attached, similar to a threaded connection advancing against another threaded connection, for example, the interaction of a nut and bolt.
Each module (502, 504, 506, 508) of the automatic elastomer depositing apparatus 500 can compete its respective process on a desired section of profiled helical surface before activating the next respective module. For example, the entire profiled helical surface of the rotor 550 can be cleaned with the cleaning module 502, then the adhesive application module 504 can apply a coating of adhesive on the entire profiled helical surface of the rotor 550, the elastomer deposition module 506 can then deposit an elastomeric coating on the entire profiled helical surface of the rotor 550, and the curing module 508 can cure the entire profiled helical surface of the rotor 550.
The invention can include the removing, applying, depositing, and curing steps in the same axial direction along the profiled helical surface. The invention can include removing, applying, depositing, and curing in a reciprocating manner, for example, one module (502, 504, 506, 508) acting from a first end of the rotor 550 to the opposing second end of the rotor 550, and a second module acting from the second end to the first end. Either of these embodiments preferably include means to traverse the profiled helical surface in two opposing directions.
Referring now to
The cleaning module 602 can remove a pre-existing elastomeric layer 601, if present, through any means known in the art. The cleaning module 602 can clean any contaminants from the interior profiled helical surface of the stator 650, for example, rust or scale. The cleaning module 602 can utilize heat, chemical, cutting, scraping, and/or abrasive action. As a stator body is typically a bore, the cleaning module 602 can also include means for removing the cleaning residue and/or removed portions of pre-existing elastomeric coating 601, for example, a vacuum device.
The adhesive application module 604 can apply a thin controlled layer of adhesive through any means known in the art, if the use of adhesive is desired. For example, an adhesive application module 604 can include one or more spray nozzles and/or brushes. An adhesive application module 604 can include a template to apply a desired thickness of adhesive therebetween. A source of adhesive can be provided in communication with the template to dispense the adhesive through a gap between the template and the profiled helical surface of the stator 650. The source of adhesive can be carried by the adhesive application module 604 itself or provided by an umbilical as is known in the art. The umbilical can include a swivel device.
In contrast to the template disclosed in reference to
As the bore of a stator is a profiled helical surface, it can be desirable to allow a module (602, 604, 606, 608), which can include a template, to track the profiled helical surface with at least one tracking mechanism. A tracking mechanism can include, for example, a wheel, skid, or a continuous belt. The tracking mechanism can be resiliently held against the profiled helical surface and connected to a module (602, 604, 606, 608) and/or template. For example, if at least one wheel is used as the tracking mechanism, it can be resiliently held against any portion of the profiled helical surface and can track the profiled helical surface. A profiled helical surface typically includes multiple lobes, with an apex of each lobe and a valley between each lobe. A wheel, or plurality of wheels, can be disposed in a valley and/or against an apex of a lobe, for example. When relative movement is imparted between the wheel and the profiled helical surface, the wheel can track the profiled helical surface. By connecting the wheel or other tracking mechanism to a module (602, 604, 606, 608) and/or template, the module and/or template can track the contours of the profiled helical surface as the module and/or template is disposed down the axis of the profiled helical surface. An apex of a lobe of a profiled helical surface, for example the stator 650, can thus remain adjacent a lobe of a template with a profiled outer surface, if utilized, during movement of the profiled helical surface with respect to the template. This can allow the gap therebetween to remain of uniform configuration along the length of the axis as a module (602, 604, 606, 608) and/or template is disposed along the profiled helical surface.
As a module (602, 604, 606, 608) and/or template can be susceptible to positioning errors with respect to a desired alignment with the profiled helical surface of the stator 650, at least one displacement servo can be utilized. A plurality of displacement servos can allow independent radial movement with respect to each module (602, 604, 606, 608), tracking mechanism, template, and/or the profiled helical surface. If a template is utilized, at least one displacement servo can allow precise control of the gap formed between the template and the adjacent section of the profiled helical surface. A displacement servo, for example, can be connected between a template, if used, and a module (602, 604, 606, 608) or tracking mechanism.
The invention can also include an elastomer deposition module 606 which deposits an elastomeric coating 607 on the profiled helical surface. The means for depositing an elastomeric coating can include means for extruding elastomer, one or more spray nozzles and/or brushes, or any other means known in the art for depositing an elastomeric coating. In a preferred embodiment, an elastomer deposition module 606 includes at least one template and means for extruding an elastomer through the gap. In the embodiment used in a stator 650, a template is designed with an outer surface that creates a desired gap between the template and the profiled helical surface of the stator 650. The template can have a profiled helical or non-helical surface without departing from the spirit of the invention. A source of an elastomer is in communication with the gap and the elastomer is extruded or otherwise disposed onto the profiled helical surface, shown in
The curing module 608 can include means for applying heat, light, or otherwise cure the elastomeric coating 607 by any means know in the art. A template can be utilized if desired to ensure uniform curing, for example, uniform heat application through a profiled heating coil.
In use, the automatic elastomer depositing apparatus 600 is disposed against the profiled helical interior surface of a stator 650, which can have a pre-existing elastomeric coating 601. Relative movement is then imparted between the automatic elastomer depositing apparatus 600 and the profiled helical surface of the stator 650. The automatic elastomer depositing apparatus 600 can allow movement of each respective module (602, 604, 606, 608) in unison or individually. The relative movement can be imparted through any type of traversal apparatus or traversal means.
During the relative movement, the cleaning module 602 can remove any pre-existing elastomeric coating 601 and/or other contaminants to expose the stator interior surface 603. Adhesive can then be applied to the cleaned stator interior surface 603 with an adhesive application module 604, which can include a template tracking the profiled helical surface with at least one tracking mechanism. An elastomeric coating 607 is then applied to the adhesive coated surface 605 with the elastomer deposition module 606, which can include a template tracking the profiled helical surface with at least one tracking mechanism. The uncured elastomeric coating 607 can then be cured with the curing module 608, to create a stator 650 with a cured elastomeric coating 609.
A carriage can allow the mounting of any of the modules (602, 604, 606, 608) in combination or alone. A carriage, if used, can connect the modules with a rod extending axially between each module. The carriage can include a drive apparatus. A traversal apparatus can be used to allow a module or a carriage, if present, to traverse the profiled helical surface. A traversal apparatus can include a drive apparatus or at least one tracking mechanism retained or resiliently held against the profiled helical surface. The tracking mechanism can include a drive apparatus.
A traversal apparatus can include a rod extending axially though the bore of the stator 650 and a drive apparatus configured to traverse the rod. Similarly, the rod can be displaced through the bore by means external to the stator 650. A track and guide, as disclosed in reference to
Although one of each type of module is illustrated in the
Referring now to
Numerous embodiments and alternatives thereof have been disclosed. While the above disclosure includes the best mode belief in carrying out the invention as contemplated by the named inventors, not all possible alternatives have been disclosed. For that reason, the scope and limitation of the present invention is not to be restricted to the above disclosure, but is instead to be defined and construed by the appended claims.
Claims
1. A method of extruding an elastomeric coating onto a progressive cavity motor component having a profiled helical surface comprising:
- providing a component of a progressive cavity motor, wherein the component has a profiled helical surface;
- disposing a carriage with a cleaning module, an adhesive application module, an elastomer deposition module, and a curing module mounted thereto along the profiled helical surface, wherein each of the four modules is point focused or has an active surface that is fully disposed around the component;
- removing a pre-existing elastomeric coating by the cleaning module from a section of the profiled helical surface as the carriage is disposed along the profiled helical surface;
- applying an adhesive by the adhesive application module onto the section of the profiled helical surface where the pre-existing elastomeric coating has been previously removed by the cleaning module;
- extruding an elastomer through a gap formed between a template of the elastomer deposition module and the profiled helical surface onto the section of the profiled helical surface where the pre-existing elastomeric coating has been previously removed by the cleaning module and where the adhesive has been previously applied by the adhesive application module; and
- curing the elastomeric coating with the curing module on the section of the profiled helical surface where the cleaning, adhesive application, and elastomer deposition modules have previously removed the pre-existing elastomeric coating, applied the adhesive, and deposited the elastomeric coating,
- wherein each of the cleaning, adhesive application, elastomer deposition, and curing modules operates while the carriage is driven along the profiled helical surface.
2. The method of claim 1 further comprising positioning the template with at least one tracking mechanism connected to the template and retained against the profiled helical surface.
3. The method of claim 1 further comprising positioning the template with at least one displacement servo disposed between the template and the carriage.
4. The method of claim 1 wherein each of the removing, applying, extruding, and curing steps occurs concurrently.
5. The method of claim 1 further comprising providing relative movement between the carriage and the profiled helical surface during the removing, applying, extruding, and curing steps.
6. The method of claim 1 further comprising providing relative movement between the carriage and each of the cleaning module, the adhesive application module, the elastomer deposition module, and the curing module during the removing, applying, extruding, and curing steps.
7. The method of claim 1 further comprising:
- connecting a guide to the carriage, the guide following at least one track extending in a straight line parallel to an axis of the profiled helical surface;
- connecting at least one tracking mechanism to the carriage, the at least one tracking mechanism retained against the profiled helical surface; and
- imparting relative rotation between the profiled helical surface and the carriage to drive the carriage along the track and the profiled helical surface.
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Type: Grant
Filed: Aug 8, 2011
Date of Patent: Feb 25, 2014
Patent Publication Number: 20120045576
Assignee: Schlumberger Technology Corporation (Sugar Land, TX)
Inventors: Geoff Downton (Minchinhampton), Lawrence Lee (Hardwicke)
Primary Examiner: Christina Johnson
Assistant Examiner: Atul P. Khare
Application Number: 13/204,949
International Classification: B29C 45/14 (20060101); B05D 3/00 (20060101); B05C 11/00 (20060101); F01C 1/10 (20060101);